import numpy as np
import pandas as pd
from umap import UMAP
from typing import List, Union
from sklearn.preprocessing import MinMaxScaler

import plotly.express as px
import plotly.graph_objects as go


def visualize_topics(topic_model,
                     topics: List[int] = None,
                     top_n_topics: int = None,
                     custom_labels: Union[bool, str] = False,
                     title: str = "<b>Intertopic Distance Map</b>",
                     width: int = 650,
                     height: int = 650) -> go.Figure:
    """ Visualize topics, their sizes, and their corresponding words

    This visualization is highly inspired by LDAvis, a great visualization
    technique typically reserved for LDA.

    Arguments:
        topic_model: A fitted BERTopic instance.
        topics: A selection of topics to visualize
        top_n_topics: Only select the top n most frequent topics
        custom_labels: If bool, whether to use custom topic labels that were defined using 
                       `topic_model.set_topic_labels`.
                       If `str`, it uses labels from other aspects, e.g., "Aspect1".
        title: Title of the plot.
        width: The width of the figure.
        height: The height of the figure.

    Examples:

    To visualize the topics simply run:

    ```python
    topic_model.visualize_topics()
    ```

    Or if you want to save the resulting figure:

    ```python
    fig = topic_model.visualize_topics()
    fig.write_html("path/to/file.html")
    ```
    <iframe src="../../getting_started/visualization/viz.html"
    style="width:1000px; height: 680px; border: 0px;""></iframe>
    """
    # Select topics based on top_n and topics args
    freq_df = topic_model.get_topic_freq()
    freq_df = freq_df.loc[freq_df.Topic != -1, :]
    if topics is not None:
        topics = list(topics)
    elif top_n_topics is not None:
        topics = sorted(freq_df.Topic.to_list()[:top_n_topics])
    else:
        topics = sorted(freq_df.Topic.to_list())

    # Extract topic words and their frequencies
    topic_list = sorted(topics)
    frequencies = [topic_model.topic_sizes_[topic] for topic in topic_list]
    if isinstance(custom_labels, str):
        words = [[[str(topic), None]] + topic_model.topic_aspects_[custom_labels][topic] for topic in topic_list]
        words = ["_".join([label[0] for label in labels[:4]]) for labels in words]
        words = [label if len(label) < 30 else label[:27] + "..." for label in words]
    elif custom_labels and topic_model.custom_labels_ is not None:
        words = [topic_model.custom_labels_[topic + topic_model._outliers] for topic in topic_list]
    else:
        words = [" | ".join([word[0] for word in topic_model.get_topic(topic)[:5]]) for topic in topic_list]

    # Embed c-TF-IDF into 2D
    all_topics = sorted(list(topic_model.get_topics().keys()))
    indices = np.array([all_topics.index(topic) for topic in topics])

    if topic_model.topic_embeddings_ is not None:
        embeddings = topic_model.topic_embeddings_[indices]
        embeddings = UMAP(n_neighbors=2, n_components=2, metric='cosine', random_state=42).fit_transform(embeddings)
    else:
        embeddings = topic_model.c_tf_idf_.toarray()[indices]
        embeddings = MinMaxScaler().fit_transform(embeddings)
        embeddings = UMAP(n_neighbors=2, n_components=2, metric='hellinger', random_state=42).fit_transform(embeddings)

    # Visualize with plotly
    df = pd.DataFrame({"x": embeddings[:, 0], "y": embeddings[:, 1],
                       "Topic": topic_list, "Words": words, "Size": frequencies})
    return _plotly_topic_visualization(df, topic_list, title, width, height)


def _plotly_topic_visualization(df: pd.DataFrame,
                                topic_list: List[str],
                                title: str,
                                width: int,
                                height: int):
    """ Create plotly-based visualization of topics with a slider for topic selection """

    def get_color(topic_selected):
        if topic_selected == -1:
            marker_color = ["#B0BEC5" for _ in topic_list]
        else:
            marker_color = ["red" if topic == topic_selected else "#B0BEC5" for topic in topic_list]
        return [{'marker.color': [marker_color]}]

    # Prepare figure range
    x_range = (df.x.min() - abs((df.x.min()) * .15), df.x.max() + abs((df.x.max()) * .15))
    y_range = (df.y.min() - abs((df.y.min()) * .15), df.y.max() + abs((df.y.max()) * .15))

    # Plot topics
    fig = px.scatter(df, x="x", y="y", size="Size", size_max=40, template="simple_white", labels={"x": "", "y": ""},
                     hover_data={"Topic": True, "Words": True, "Size": True, "x": False, "y": False})
    fig.update_traces(marker=dict(color="#B0BEC5", line=dict(width=2, color='DarkSlateGrey')))

    # Update hover order
    fig.update_traces(hovertemplate="<br>".join(["<b>Topic %{customdata[0]}</b>",
                                                 "%{customdata[1]}",
                                                 "Size: %{customdata[2]}"]))

    # Create a slider for topic selection
    steps = [dict(label=f"Topic {topic}", method="update", args=get_color(topic)) for topic in topic_list]
    sliders = [dict(active=0, pad={"t": 50}, steps=steps)]

    # Stylize layout
    fig.update_layout(
        title={
            'text': f"{title}",
            'y': .95,
            'x': 0.5,
            'xanchor': 'center',
            'yanchor': 'top',
            'font': dict(
                size=22,
                color="Black")
        },
        width=width,
        height=height,
        hoverlabel=dict(
            bgcolor="white",
            font_size=16,
            font_family="Rockwell"
        ),
        xaxis={"visible": False},
        yaxis={"visible": False},
        sliders=sliders
    )

    # Update axes ranges
    fig.update_xaxes(range=x_range)
    fig.update_yaxes(range=y_range)

    # Add grid in a 'plus' shape
    fig.add_shape(type="line",
                  x0=sum(x_range) / 2, y0=y_range[0], x1=sum(x_range) / 2, y1=y_range[1],
                  line=dict(color="#CFD8DC", width=2))
    fig.add_shape(type="line",
                  x0=x_range[0], y0=sum(y_range) / 2, x1=x_range[1], y1=sum(y_range) / 2,
                  line=dict(color="#9E9E9E", width=2))
    fig.add_annotation(x=x_range[0], y=sum(y_range) / 2, text="D1", showarrow=False, yshift=10)
    fig.add_annotation(y=y_range[1], x=sum(x_range) / 2, text="D2", showarrow=False, xshift=10)
    fig.data = fig.data[::-1]

    return fig
